JPH08294090A - Recorder for digital image data and its method - Google Patents

Abstract

PURPOSE: To improve the efficiency of data compression by fixing an ineffective part and compressing data for each block when an image with a different aspect ratio is obtained from a standard image. CONSTITUTION: An image formed onto a light receiving face of a CCD 12 is a standard image having an aspect ratio of 4:3. Image data are arranged to be the standard image by a data arrangement generator 15 via a data reading 13, a luminance color difference signal generator 14, and image data of an invalid part are fixed to a prescribed level by an image data fixing processing section 16. Then, only color difference data are given to a data compressor 19 together with luminance data via sampling converters 17A, 17B. The data compression is conducted in the unit of blocks each comprising 8×8 picture elements and the data quantity after compression is fixed to be a prescribed quantity. High compression is attained for the invalid image data, resulting that low compression is enough for the valid image data. The compressed data are recorded on a magnetic tape 8 from a magnetic head 21 via a data string generator 20.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a digital image data recording apparatus and method for compressing image data and recording it on a recording medium for each block composed of a predetermined number of pixels.

[0002]

BACKGROUND OF THE INVENTION A wide-screen television system having a screen aspect ratio of 16: 9 has been realized, while a standard television system has a screen aspect ratio of 4: 3. Since two types of television systems coexist in this way, there is also a demand for a technique for converting image data representing an image having one aspect ratio into image data representing an image having the other aspect ratio. Examples of such image data conversion techniques are described in JP-A-5-3555 and JP-A-5-199547.

On the other hand, for image data processing, the image data compression technique is indispensable because the image data amount for one screen becomes enormous.

Two types of television systems coexist, and the image data compression technique is also used when converting image data representing an image with one aspect ratio into image data representing an image with the other aspect ratio. Especially, efficient image data compression is required.

[0005]

DISCLOSURE OF THE INVENTION The present invention has at least two types of television systems coexisting, and is effective in converting image data representing an image having one aspect ratio into image data representing an image having the other aspect ratio. The purpose is to perform image data compression well.

According to a first aspect of the present invention, there is provided a digital image data recording apparatus, wherein an image pickup means for outputting standard image data representing a subject image obtained by picking up an image of a subject and a standard represented by the standard image data outputted from the image pickup means. In order to leave a part that becomes a wide display image from the image, in at least one of the upper and lower parts of the standard image,
Image data level fixing means for fixing the level of the image data in the range of an integral multiple of the unit block for data compression in the vertical direction to a fixed level, and fixed to the fixed level by the image data level fixing means. Data for compressing the image data and the image data representing the portion remaining as the wide display image from the standard image so that the data amount for one screen after compression is a predetermined data amount for each unit block It is characterized by comprising a compression means and a recording control means for recording the image data compressed by the data compression means on a recording medium.

The first invention also provides a method of recording digital image data. That is, the subject is imaged to obtain standard image data representing the subject image, and at least one of the upper and lower portions of the standard image is left so that the standard image represented by the standard image data obtained by the imaging remains a wide display image. An image in which the level of the image data in the range of an integral multiple length of the unit block for data compression in the vertical direction is fixed to a certain level in one of the portions and fixed to the certain level by the image data level fixing process. The data and the image data representing the portion remaining as the wide display image from the standard image are subjected to data compression for each unit block so that the data amount for one screen after compression becomes a predetermined data amount, and the data is compressed. It is characterized in that the compressed image data is recorded on a recording medium.

The standard image represented by the standard image data obtained by the above image capturing is a normal display image having an aspect ratio of 4: 3, for example. To enable wide display with an aspect ratio of 16: 9 from such standard image data, image data representing a wide image must be obtained from the standard image data.

In the first aspect of the invention, the level of the image data of the standard image data other than the part used for the wide display image is fixed to a fixed level. As a result, the image data that is not fixed at a fixed level represents a wide display image.

The image data fixed to a fixed level and the image data representing the portion remaining as the wide display image from the standard image are subjected to data compression for each unit block composed of a predetermined number of pixels. Image data fixed at a certain level can be compressed at a high compression rate, and efficient data compression is possible. Particularly, in the first aspect of the invention, the portion for fixing the level of the image data to a fixed level is set within the range of the length which is an integral multiple of the block. Therefore, the standard image represented by the standard image data is divided into blocks,
When data compression is applied to each block, the image data level in the block is always a constant level for the part fixed to a certain level, and image data fixed to a certain level and image data not fixed to a certain level. Never mix. Therefore, efficient data compression becomes possible.

Identification data indicating that the image data level fixing process and the data compression process have been performed are generated, and the image data compressed by the data compression process is stored in the image data recording area of the recording medium. It is preferable that the data is recorded and the identification data generated by the identification data generation process is recorded in an auxiliary recording area other than the image data recording area of the recording medium.

In this case, the recording apparatus and the recording method of the first invention are provided with the following reproducing function and reproducing process.

In a case where the first invention is a recording apparatus, the reading means for reading the compressed image data recorded in the image data recording area and the identification data recorded in the auxiliary recording area, respectively, are read by the reading means. Based on the data decompression means for decompressing the compressed image data and the identification data read by the reading means, the image data / level fixing processing is performed on the image data decompressed by the data decompression means. The image display control means is characterized by including image display control means for controlling image display so that an image represented by image data other than the generated image data is displayed in a predetermined display area of the display area of the display device.

When the first invention is a recording method, the compressed image data recorded in the image data recording area and the identification data recorded in the auxiliary recording area are read, and the read compressed image data is recorded as data. An image represented by image data other than the image data subjected to the image data / level fixing process among the image data subjected to the data expansion by the data expansion process based on the read identification data is expanded. It is characterized as displaying in a predetermined display area of the display area of the display device.

Thus, the wide image is displayed in the predetermined display area.

Wide display image data can be obtained from normal display standard image data, and a wide image can be displayed.

A digital image data recording apparatus according to a second aspect of the present invention includes a solid-state electronic image pickup device for generating standard image data having a data amount n times as large as the unit image data, and the solid-state electronic image pickup device is used to capture an object. Image pickup means for outputting the standard image data representing a subject image obtained by picking up an image of the subject, image data dividing means for dividing the standard image data output from the image pickup means into n unit image data, and the image data division Data is vertically compressed in at least one of the upper and lower parts of the standard image so that the image obtained by combining the unit image data divided into n pieces by the means becomes a wide display image. Image data level fixing means for fixing the level of image data in the range of an integral multiple of the unit block for For the image data fixed to a fixed level by the data level fixing means and the image data representing the portion remaining as the wide display image from the standard image, the data amount for one screen after compression becomes the predetermined data amount. Data compression means for performing data compression for each unit block, and recording control means for recording n unit image data data compressed by the data compression means in n unit image data recording areas are recorded. It is characterized by having.

In the digital image data recording method according to the second aspect of the present invention, a subject is imaged by using a solid-state electronic image pickup device which generates standard image data having a data amount n times as large as the unit image data, Is obtained by dividing the standard image data obtained by the image pickup into n unit image data, and combining the unit image data divided into n by the image data dividing process. In order to leave a portion where the image becomes a wide display image, in at least one of the upper and lower portions of the standard image, the image data in the range of the length of an integral multiple of the unit block for data compression in the vertical direction is The level is fixed to a fixed level, and the wide display is made from the image data and the standard image fixed to a fixed level by the image data / level fixing process. For the image data representing the portion that remains as an image, the data compression is performed for each unit block so that the data amount for one screen after compression becomes a predetermined data amount, and the data is compressed by the data compression process. One unit image data is divided into n unit image data recording areas and recorded.

The data amount of the unit image data is about 350,000 pixels, for example.

In the second invention, the data amount of the standard image data obtained by the image pickup is n times (for example, 700,000 pixels) the data amount of the unit image data, and the standard image represented by the standard image data is, for example, It has an aspect ratio of 4: 3 of a normal image. In digital video tape recorders, for example, the standard is set so that unit image data of about 350,000 pixels of 720 pixels in the horizontal direction and 480 pixels in the vertical direction can be recorded in a unit recording area (for example, 10 continuous tracks). Therefore, the standard image data cannot be recorded as it is. Therefore, in the second invention, the standard image data is
It is divided into individual unit image data. This enables recording according to the conventional standard.

According to the second aspect of the invention, when the standard image data representing the normal image is divided into unit image data and recorded on the recording medium, the image data representing the wide image is obtained and the data compression is performed efficiently. It is possible.

In the second invention, the level of the image data of the portion other than the portion which becomes the wide image by combining the unit image data divided into n pieces is fixed to a constant level. As a result, a wide display image is represented by synthesizing the remaining image data that is not fixed to a fixed level.

The divided image data is subjected to data compression for each block composed of a predetermined number of pixels. Image data fixed at a certain level is compressed at a high compression rate. Also in the second aspect of the invention, the portion for fixing the level of the image data to a fixed level is set within the range of the integral multiple length of the block. Therefore,
When the standard image represented by the standard image data is divided into blocks and data compression is performed for each block,
As for the portion fixed to a fixed level, the image data level in the block is always a fixed level, and image data fixed to a fixed level and image data not fixed to a fixed level do not coexist. Therefore, efficient data compression becomes possible.

Identification data representing that the image data level fixing process and the data compression process have been performed are generated, and n unit image data data-compressed by the data compression process are converted into n units of a recording medium. It is preferable to separately record the individual unit image data recording areas and record the identification data generated by the identification data generating process in an auxiliary recording area other than the image data recording area of the recording medium.

In this case as well, the recording apparatus and the recording method of the second invention have the following reproducing function and reproducing process as in the first invention.

In the case where the second invention is a recording apparatus, the reading means for reading the compressed image data recorded in the image data recording area and the identification data recorded in the auxiliary recording area, respectively, are read by the reading means. On the basis of the data decompression means for decompressing the compressed data and the identification data read by the reading means, the image data / level fixing process is performed on the image data decompressed by the data decompression means. The image display is controlled so that an image represented by image data other than the image data, which becomes a wide display image by being combined, is displayed in a predetermined display area of the display area of the display device. It is characterized as having an image display control means.

When the second invention is a recording method, the compressed image data recorded in the image data recording area and the identification data recorded in the auxiliary recording area are read, and the read compressed image data is converted into data. It is an image represented by image data other than the image data subjected to the image data level fixing process among the image data subjected to the data decompression process based on the decompressed and read identification data. An image that becomes a wide display image by being combined by the above is characterized as being displayed in a predetermined display area of the display area of the display device.

As a result, the wide image is displayed in the predetermined display area.

The image data recording apparatus of the third invention includes a solid-state electronic image pickup device for generating standard image data having a data amount n times as large as the unit image data, and the solid-state electronic image pickup device picks up an image of a subject. Image data for outputting the standard image data representing the subject image obtained by dividing the standard image data output from the image capturing means into n unit image data so that each represents one frame image. Dividing means, at least one of the upper and lower portions of the standard image so that an image represented by the unit image data divided into n pieces by the image data dividing means becomes a wide display image,
Image data level fixing means for fixing the level of the image data in the range of an integral multiple of the unit block for data compression in the vertical direction to a fixed level, and fixed to the fixed level by the image data level fixing means. Data for compressing the image data and the image data representing the portion remaining as the wide display image from the standard image so that the data amount for one screen after compression is a predetermined data amount for each unit block It is characterized in that it is provided with a compressing means and a recording control means for recording the n unit image data data compressed by the data compressing means by dividing them into n unit image data recording areas.

The third invention also provides a method of recording image data. That is, an image of a subject is picked up using a solid-state electronic image pickup device that generates standard image data having a data amount that is n times the amount of unit image data, the standard image data representing the subject image is obtained, and the standard image data is obtained by the image pickup. A portion in which the standard image data is divided into n unit image data so that each represents one frame image, and the image represented by the unit image data divided into n by the image data division process becomes a wide display image. , The image data level in the range of an integral multiple length of the unit block for data compression in the vertical direction is fixed to a constant level in at least one of the upper and lower parts of the standard image, The image data fixed to a fixed level by the image data level fixing process and the portion remaining as the wide display image from the standard image For the image data to be expressed, data compression is performed for each unit block so that the data amount for one screen after compression becomes a predetermined data amount, and n unit image data data compressed by the data compression process. Is divided into n unit image data recording areas and recorded.

The data amount of the unit image data is about 350,000 pixels, for example.

In the third invention, the data amount of the standard image data output from the image pickup means is n times (for example, 700,000 pixels) the data amount of the unit image data. In digital video tape recorders, for example, the standard is set so that unit image data of about 350,000 pixels of 720 pixels in the horizontal direction and 480 pixels in the vertical direction can be recorded in a unit recording area (for example, 10 continuous tracks). Therefore, the standard image data cannot be recorded as it is. Therefore, in the third invention, the standard image data is
Each of them constitutes one frame and is divided into n unit image data. This allows recording according to the conventional standard. Moreover, in the third invention, the image represented by the divided unit image constitutes one frame, so that the image constituting one frame can be obtained only by reading even during reproduction.

According to the third aspect of the invention, the level of the image data of the above-mentioned unit image data divided so as to form one frame, excluding the portion used for the wide display image, becomes a constant level. Fixed. As a result, the remaining image data that is not fixed at a fixed level represents a wide display image.

The image data fixed to a constant level and the image data representing the portion remaining as the wide display image from the standard image are subjected to data compression for each block composed of a predetermined number of pixels. Image data fixed at a certain level can be compressed at a high compression rate, and efficient data compression is possible. Particularly, in the third aspect of the invention, the portion for fixing the level of the image data to a constant level is set within the range of the length which is an integral multiple of the above block. Therefore, when the standard image represented by the standard image data is divided into blocks and data compression is performed for each block, the image data level in the block is always a constant level for the part fixed at a constant level, Fixed image data and image data not fixed to a fixed level do not coexist. Therefore, efficient data compression becomes possible.

Identification data representing that the image data level fixing process and the data compression process have been performed are generated, and the data-compressed n unit image data are stored in the unit image data recording area of the recording medium. Preferably, the identification data generated by the identification data generation process is recorded in an auxiliary recording area other than the image data recording area of the recording medium.

Also in this case, the recording apparatus and the recording method according to the third aspect of the invention are provided with a reproducing function and a reproducing process.

In the case of the recording apparatus according to the third aspect of the invention, the compressed image data recorded in the image data recording area and the identification data recorded in the auxiliary recording area are read by the reading means and read by the reading means. Based on the data decompression means for decompressing the compressed image data and the identification data read by the reading means, the portion of the image which becomes the wide display image of the image data subjected to the data decompression by the data decompression means. It is characterized as having an image display control means for controlling the image display so that the image represented by the image data is displayed in a predetermined display area of the display area of the display device.

When the third invention is a recording method, the compressed image data written in the image data recording area and the identification data recorded in the auxiliary recording area are read, and the read compressed image data is expanded. Then, based on the read identification data, the image represented by the image data of the image portion which becomes the wide display image among the image data subjected to the data extension by the data extension processing is displayed in the display area of the display device. It is characterized as being displayed in a predetermined display area.

[0039]

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIGS. 1 to 8 show a first embodiment of the present invention.

Before explaining the structure and operation of the digital video tape recorder,
The existing standard industry standards regarding the recording method on the magnetic tape by the tape recorder will be described.

The recording format of the magnetic tape is shown in FIG. 8 (A).
And (B). FIG. 8A shows tracks Tr of the magnetic tape 8, and a large number of tracks Tr are formed at a constant angle in an oblique direction with respect to the longitudinal direction of the magnetic tape 8. Consecutive of these many tracks Tr
Digital image data for one frame is recorded using 10 tracks.

The track format is shown in FIG. 8 (B). One track Tr includes a subcode recording area, a video recording area, an auxiliary recording area, an audio recording area, and a track information recording area. Information such as a time code and an absolute track number for high speed search is recorded in the sub code recording area. Digital image data representing a subject image is recorded in the video recording area. Data representing sound is recorded in the audio recording area. Information serving as a reference of the track Tr for the magnetic head to trace the center of the track Tr is recorded in the track information recording area. Auxiliary recording areas are provided discretely, and additional information is recorded in this auxiliary recording area.
Illustrations of the gaps provided between the regions are omitted.

The CCD used in the image pickup section of a digital video tape recorder is generally (conventional) a horizontal C
72 horizontal direction with a CD transfer clock frequency of 13.5 MHz
A pixel with about 350,000 pixels of 0 pixels and 480 pixels in the vertical direction is used. Digital image data for one frame obtained by using such a CCD is recorded on the magnetic tape 8
Recorded on 10 tracks. This is an existing standard.

FIG. 1 is a block diagram showing the electrical construction of the recording system of a digital video tape recorder. FIG. 3 shows an image represented by the image data flowing in the digital video tape recorder shown in FIG.

The digital video tape shown in FIG.
The recorder converts image data for a normal display image having an aspect ratio of 4: 3 obtained by imaging into image data for a wide display image having an aspect ratio of 16: 9 and records the image data.

Referring to FIG. 1, the image of the subject is the image pickup lens 11
An image is formed on the light receiving surface of the CCD 12 by. The CCD 12 has a pixel number of 720 pixels in the horizontal direction and 480 pixels in the vertical direction. In the digital video tape recorder shown in FIG. 1, the image represented by these pixels is a normal display image having an aspect ratio of 4: 3. It is said that The analog video signal representing the subject image is CC when the subject is imaged.
It is output from D12 and given to the data read circuit 13. It is converted into digital image data in the data reading circuit 13 and given to the luminance / color difference generating circuit 14. The luminance / color difference generation circuit 14 is a circuit that generates and outputs luminance data Y and color difference data RY and BY from input image data.

The luminance data Y, the color difference data RY and the color difference data BY output from the luminance / color difference generating circuit 14 are given to the data array generating circuits 15A, 15B and 15C, respectively. The data array generation circuits 15A, 15B and 15C convert the luminance data Y and the color difference data RY and BY, which are serially applied, into image data of 720 horizontal pixels and 480 vertical pixels as shown in FIG. This is a circuit for arranging data. Luminance data Y and color difference data RY output from the data array generation circuits 15A, 15B and 15C.
And the color difference data BY are supplied to image data fixing circuits 16A, 16B and 16C included in the image data fixing device 16, respectively.

Image data fixing circuits 16A, 16B and 16
C is input luminance data Y of horizontal 720 pixels, vertical direction 480 pixels, color difference data RY and color difference data BY
Is a circuit that makes valid image data only for image data for 720 pixels in the horizontal direction and 360 pixels in the vertical direction, and for other image data, fixes the image data level to a fixed level, for example, the black level, and makes it invalid image data. Is. In FIG. 3, the portion of the image represented by the invalid image data is shown by hatching. By the image data fixing circuits 16A, 16B and 16C, only the image data of 720 pixels in the horizontal direction and 360 pixels in the vertical direction are treated as effective image data, whereby image data representing a wide image having an aspect ratio of 16: 9 can be obtained. . When an image represented by 720 pixels in the horizontal direction and 480 pixels in the vertical direction is regarded as a normal display image with an aspect ratio of 4: 3, a wide display image with an aspect ratio of 16: 9 has 720 pixels in the horizontal direction and 360 in the vertical direction. This is because it is represented by pixels.

Image data fixing circuits 16A, 16B and 16
The vertical image portion of the image portion represented by the image data that is invalid data by C is defined as an integral multiple of 8 pixels. Horizontal direction 720 as shown in FIG.
When the image data representing an image of 720 pixels in the horizontal direction and 360 pixels in the vertical direction is valid from the image data representing the image of 480 pixels in the vertical direction, it is considered that the invalid parts are the upper part and the lower part of the image. However, m pixels (for example, 64 pixels) for the upper part and n for the lower part
Pixels (eg, 56 pixels) are invalidated. The invalid image portion does not necessarily have to be divided into the upper portion and the lower portion of the image, and only the upper portion or only the lower portion may be invalidated.

Image data fixing circuits 16, 16B and 16C
The image part represented by the image data that is regarded as invalid data by the vertical image part is defined as an integral multiple of 8 pixels in order to efficiently perform data compression, which will be described later. The details will be described later in the description of the data compression circuit 19.

The color difference data R-Y and B-Y output from the image data fixing circuits 16B and 16C are given to sampling conversion circuits 17B and 17C, respectively. The sampling conversion circuits 17B and 17C are circuits that thin out the input color difference data RY and BY by changing the timing of sampling the data.
72 in the horizontal direction by the sampling conversion circuits 17B and 17C
Image data with 0 pixels and 480 pixels in the vertical direction is 180 pixels in the horizontal direction.
Pixels are thinned out and output so as to obtain image data of 480 pixels in the vertical direction. Sampling conversion circuit
The color difference data R-Y and B-Y output from 17B and 17C are applied to the data compression circuit 19. The data compression circuit 19 is also supplied with the luminance data Y output from the image data fixing circuit 16A.

The data compression circuit 19 is a DCT (Discrete Cos).
ine Transform) is used to compress image data.

In the data compression circuit 19, first, a blocking process is performed, and the input luminance data and the image represented by the color difference data RY and BY are divided into blocks each having 8 pixels in the horizontal direction and 8 pixels in the vertical direction. Be divided.

FIG. 4 (A) shows a screen represented by one frame of luminance data Y, and FIG. 4 (B) shows a screen represented by one frame of color difference data RY or BY. ing.

The number of pixels of the luminance data Y is 720 pixels in the horizontal direction and 480 pixels in the vertical direction. Therefore, the brightness data Y
As shown in Fig. 4 (A), it is divided into 90 blocks in the horizontal direction and 60 blocks in the vertical direction. The number of pixels of the color difference data RY and BY is 180 pixels in the horizontal direction and 480 pixels in the vertical direction. Therefore, the color difference data R-Y and B-Y are set in the horizontal direction as shown in FIG.
Divided into 22.5 blocks. Further, since the right end block is a small block having 4 pixels in the horizontal direction and 8 pixels in the vertical direction, one block is formed from two small blocks as shown in FIG.

In the blocking process, the macro blocking process is performed on the luminance data Y and the color difference data R-Y and B-Y divided into blocks of 8 pixels in the horizontal direction and 8 pixels in the vertical direction. As shown in FIG. 5, the macro-blocking processing is performed by a macro composed of luminance data Y consisting of four blocks and color difference data RY and BY located at the same position as the four blocks on the screen. -A circuit that generates blocks. The shuffling process is performed on the luminance data Y and the color difference data R-Y and B-Y which are macro-blocked in the macro-blocking process.

At the time of shuffling processing, an image for one screen composed of macro blocks is constructed. This image is composed of 22.5 macro blocks in the horizontal direction and 60 macro blocks in the vertical direction as shown in FIG.

The shuffling process is performed by selecting macro blocks from different parts according to a certain rule and sequentially repeating them. In the example shown in FIG. 7 five macro blocks MB _A to MB _E from one image is selected. These five selected macro blocks MB _{A to} MB
_E image data DCT transformation on is performed data compression by being subjected to, the amount of image data of five macro blocks MB _A to MB _E after data compression is a fixed length and a predetermined.

The digital video tape shown in FIG.
In the recorder, at least one of the plurality of macro blocks selected in the shuffling process has the image data level fixed in the image data fixing circuits 16A, 16B and 16C as shown in FIG. Is selected from the portion represented by the image data that has been made invalid data. Since the image data level of the portion represented by the invalid image data is fixed, extremely high compression is possible.
On the other hand, the amount of data after the data compression of a plurality of macro blocks (here, five) obtained by shuffling is constant, so a macro block selected from the part represented by the invalid image data. The compression rate for macro blocks other than blocks is low,
As a result, a high quality image can be obtained during reproduction.

Further, in the digital video tape recorder shown in FIG. 1, the image data fixing circuits 16A and 16B are provided.
The image portion in the vertical direction of the image portion represented by the image data that is invalid data in the image data fixing process at 16C and 16C is defined as an integral multiple of 8 pixels. Therefore, the macro blocks selected from the image portion represented by the invalid image data are all generated by the invalid image data and do not include the valid image data. Therefore, high compression is possible for the macro block selected from the image portion represented by the invalid image data and fixed length for the macro block selected from the image portion represented by the valid image data. Even with data compression, low compression is sufficient. This is the reason why the vertical portion of the portion represented by invalid data is defined as an integral multiple of 8 pixels.

The compressed image data output from the data compression circuit 19 is supplied to the data string creation circuit 20. The data string creating circuit 20 includes image data fixing circuits 16A, 16B and 16
Fixed value setting information representing the number of pixels (m, n) in the vertical direction represented by the image data that is invalid data in C is also given. In the data string creating circuit 20, the compressed image data is recorded in the video recording area A ₂ of the magnetic tape 8 and the data string is generated so that the fixed value setting information is recorded in the auxiliary recording area A ₃ . The data output from the data string creating circuit 20 is given to the magnetic head 21. The magnetic head 21 records the compressed image data in the video recording area A ₂ of the magnetic tape 8 and the fixed value setting information in the auxiliary recording area A ₃ .

FIG. 2 is a block diagram showing the electrical construction of the reproducing system of the digital video tape recorder.

The compressed image data recorded in the video recording area A ₂ of the magnetic tape 8 and the fixed value setting information recorded in the auxiliary recording area A ₃ are read by the magnetic head 31 and demodulated in the data demodulation circuit 32. . The fixed value setting information demodulated in the data demodulation circuit 32 is given to the video signal generation and display control circuit 35. The demodulated compressed image data is divided by the data demodulation circuit 32 into luminance data Y, color difference data BY and RY and output. The compressed luminance data Y, color difference data BY and RY output from the data demodulation circuit 32 are given to the data expansion circuit 33 and subjected to data expansion processing.

The data-expanded luminance data Y is supplied to the video signal generation and display control circuit 35. On the other hand, the decompressed color difference data BY and RY are supplied to the sampling conversion circuit 34, and the horizontal direction is 180 pixels and the vertical direction is 180 pixels.
It is restored from 480 pixels to 720 pixels in the horizontal direction and 480 pixels in the vertical direction. Output color difference data B-of the sampling conversion circuit 34
Y and RY are video signal generation and display control circuits 35
Given to.

The video signal generation and display control circuit 35 is
Given luminance data Y, color difference data BY and R-
A circuit that generates a video signal from Y so that it can be displayed on the display device 41 and controls the display position on the display screen of the display device 41. Display device 41 is horizontal 72
If it is for normal display with 0 pixels and 480 pixels in the vertical direction, the image data is 720 pixels in the horizontal direction and 360 in the vertical direction.
The level of the portion other than the pixel is fixed, so that it becomes black, for example, on the display screen. This blackened position, in other words, horizontal 720 pixels, vertical 360
The display control circuit controls the position where the pixel image is displayed.
35. Even if the invalid portion or the upper portion or the lower portion of the screen is biased, it is possible to display at a desired position such as the central portion of the display screen by the display control in the circuit 35. Whether or not the image data fixing process is performed can be known from the fixed value setting information provided from the data demodulation circuit 32.

9 to 12 show another embodiment.

FIG. 9 is a block diagram showing the electrical construction of the recording system of the digital video tape recorder. 9, the same components as those shown in FIG. 1 are designated by the same reference numerals and the description thereof will be omitted.

The digital video tape shown in FIG.
The recorder can record image data representing a high quality normal display image and image data representing a high quality wide display image in accordance with the conventional recording standard.

The digital video tape shown in FIG.
In the recorder, a CCD 12A having a large number of pixels is used as an image sensor in order to obtain high quality image data. CC
D12A is horizontal 720 as shown at the left end of FIG.
Pixels, vertical 960 pixels = about 700,000 pixels. With this image data of 720 pixels in the horizontal direction and 960 pixels in the vertical direction, a high quality normal image having an aspect ratio of 4: 3 is displayed. The video signal output from the CCD 12A is a data read circuit 13, a luminance color difference generation circuit.
The luminance data Y and the color difference data RY and BY for 720 pixels in the horizontal direction and 960 pixels in the vertical direction are obtained through 14 and the data array generation circuits 15A, 15B and 15C. The luminance data Y, the color difference data RY and BY are
It is applied to the image division circuits 22A, 22B and 22C, respectively.

According to the conventional recording standard of a digital video tape recorder, the horizontal direction is 720 pixels and the vertical direction is 48 pixels.
Image data for one frame of 0 pixels = approx. 350,000 pixels is recorded in the video recording area of 10 consecutive tracks. Therefore, 720 pixels in the horizontal direction and 960 pixels in the vertical direction obtained from the CCD 12A = approx. 70 pixels. It is not possible to directly record the image data of 10,000 pixels. Therefore, in the digital video tape recorder shown in FIG. 9, the image data of 720 pixels in the horizontal direction and 960 pixels in the vertical direction = approximately 700,000 pixels is converted into two images of 720 pixels in the horizontal direction and 480 pixels in the vertical direction = approximately 350,000 pixels. The image data is divided and then recorded on the magnetic tape 8. The image division circuits 22A, 22B and 22C perform the division processing of the image data for each of the luminance data Y, the color difference data RY and BY.

In the image dividing circuit 22A, the luminance data Y of about 700,000 pixels is divided into two, and the image data fixing circuit 23 is divided.
A and 23B respectively. Color difference data RY
Similarly to the luminance data Y, the chrominance data RY and BY which are divided into two are also used for the image data fixing circuits 23C and 23D and 23E and 23.
Each is given to F.

The image data fixing circuits 23A and 23B are
Luminance data Y of two given horizontal 720 pixels and vertical 480 pixels = approximately 350,000 pixels (in other words, horizontal direction
Brightness data Y of 720 pixels and 960 pixels in the vertical direction to 720 pixels in the horizontal direction and 720 pixels in the vertical direction is used as valid data, and for other brightness data Y, the brightness data level is a constant level (for example, black level).
It is a circuit that makes invalid data by fixing to. When an image with 720 pixels in the horizontal direction and 960 pixels in the vertical direction is regarded as a high-quality normal display image with an aspect ratio of 4: 3, a high-quality wide display image with an aspect ratio of 16: 9 has 720 pixels in the horizontal direction. Since it is represented by 720 pixels in the vertical direction, image data of 720 pixels in the horizontal direction and 720 pixels in the vertical direction are valid data. Of the luminance data divided into two, one of the luminance data Y is m in the vertical direction.
The level of the brightness data Y for pixels is fixed, and the level of the brightness data Y for n pixels in the vertical direction of the other brightness data Y is fixed. The number of pixels when 720 pixels are subtracted from 960 pixels is the sum of m pixels and n pixels (960 −720
= M + n).

Further, image data fixing circuits 23A and 23
In B, the pixel numbers m and n in the vertical direction of the image portion (shown by hatching in FIG. 11) in which the data level is fixed to a constant level are set to integer multiples of 8 pixels. Therefore, like the digital video tape recorder shown in FIG. 1, efficient data compression is possible with the digital video tape recorder shown in FIG. The reason for this has already been explained, so avoid further duplication.

The image data fixing circuits 23C, 23D and 23E are also used for the color difference data RY and BY.
23 and 23F, the data fixing process similar to the process for the luminance data Y is performed. The image data fixing circuits 23C and 23E perform the same processing as the image data fixing circuit 23A, and the image data fixing circuits 23D and 23F.
Performs the same processing as the image data fixing circuit 23B.
Therefore, it will be understood that the image data fixing process is performed on the color difference data R-Y and B-Y similarly to the luminance data Y.

The fixed value setting information of the number of pixels m and n in the vertical direction represented by the image data whose data level is fixed is obtained from the image data fixing device 23 by the data string creating circuit.
Given to 20. In the data string creating circuit 20, a data string is created such that image data is recorded in the video recording area A ₂ of the track of the magnetic tape 8 and fixed value setting information is recorded in the auxiliary recording area A _3. Recorded in. In the digital video tape recorder shown in FIG. 9, image data of about 350,000 pixels obtained by dividing the image data of about 70 pixels into two 20
The tracks are recorded separately.

FIG. 10 is a block diagram of the digital video stream shown in FIG.
It is a block diagram which shows the electric constitution of the circuit which reproduce | regenerates the image data recorded on the tape recorder. Also in FIG. 10, the same components as those shown in FIG.

When data of 20 consecutive tracks is read from the magnetic tape 31, image data representing the image shown at the left end of FIG. 12 is obtained. These image data are given to the video signal generation and display control circuit 35 to generate a video signal suitable for image display. The video signal is given to the image synthesis circuit 36, and the horizontal direction is 720 pixels and the vertical direction is 72 pixels.
Image combining processing is performed so that a high-quality wide display image composed of 0 pixels can be obtained. The high-quality wide display image is displayed on the display device 41 based on the display control. If necessary, adjust the image data amount so that it has 720 horizontal pixels, 360 vertical pixels or 720 horizontal pixels, and 480 vertical pixels, and displays a wide display image of normal image quality or a normal display image of normal image quality on a display device. It may be displayed on 41.

FIG. 13 shows still another embodiment, showing an image represented by image data obtained in the recording process of a digital video tape recorder.

The process shown in FIG.
Image data for high-quality normal display images with 0 pixels and 960 pixels in the vertical direction = approximately 700,000 pixels were obtained, and from this obtained image data, two wide images with normal image quality of 720 pixels in the horizontal direction and 360 pixels in the vertical direction were obtained. The image data for the display image is obtained. The image data for the two wide display images of normal image quality thus obtained may be displayed as it is as a wide display image of normal image quality of 720 pixels in the horizontal direction and 360 pixels in the vertical direction. Direction 72
It may be displayed as a wide display image with 0 pixels and 720 pixels in the vertical direction.

Image data representing the image shown in FIG. 13 can be recorded by the digital video tape recorder shown in FIG.

By picking up an image of a subject using the CCD 12A, image data for a high quality normal display image of 720 pixels in the horizontal direction and 960 pixels in the vertical direction can be obtained. This image data is stored in the image division circuits 22A, 22B and 22C,
Each of the luminance data Y and the color difference data RY and BY is divided into an image composed of image data of even lines and an image composed of image data of odd lines. This allows 720 pixels in the horizontal direction and 48 pixels in the vertical direction.
Two image data of 0 pixels = about 350,000 pixels (luminance data Y, color difference data RY and BY) are obtained. The subsequent process is the same as the process described with reference to FIG.
For each of the image data composed of even-numbered lines and the image data composed of odd-numbered lines, the level of the image data excluding 720 pixels in the horizontal direction and 360 pixels in the vertical direction is fixed to a constant level (also in Fig. 13 The portion of the image represented by the fixed image data is indicated by hatching) and is recorded on the magnetic tape 8. In the example shown in Figure 13, 720 pixels in the horizontal direction and 480 pixels in the vertical direction.
Since there are two pieces of data of pixels = about 350,000 pixels, recording is performed on the magnetic tape 8 by using 10 continuous tracks, 20 continuous tracks.

The image data recorded on the magnetic tape 8 in this way is read out at the time of reproduction, and the image data is combined so that even lines and odd lines alternate so that 720 pixels in the horizontal direction and 720 pixels in the vertical direction. A high quality wide display image of 720 pixels can be obtained. In addition, a normal display image with a normal image quality of 720 pixels in the horizontal direction and 360 pixels in the vertical direction can be obtained without image composition.

[Brief description of drawings]

FIG. 1 shows an embodiment of the present invention.
It is a block diagram which shows the electric constitution of the recording system of a video tape recorder.

FIG. 2 is a block diagram showing an electrical configuration of a reproduction system of a digital video tape recorder.

FIG. 3 shows an example of an image represented by image data.

FIG. 4A shows a screen represented by 1 frame of luminance data, and FIG. 4B shows a screen represented by 1 frame of color difference data.

FIG. 5 shows block generation processing at the right end of the screen.

FIG. 6 shows a macro block

FIG. 7 shows a shuffling process.

[Figure 8] (A) shows the format of the magnetic tape, (B)
Indicates the track format.

FIG. 9 shows another embodiment and is a block diagram showing an electrical configuration of a recording system of a digital video tape recorder.

FIG. 10 is a block diagram showing an electrical configuration of a reproducing system of the digital video tape recorder.

FIG. 11 shows an example of an image represented by image data.

FIG. 12 shows an example of an image represented by image data.

FIG. 13 shows an example of an image represented by image data.

[Explanation of symbols]

12,12A CCD 16A, 16B, 16C, 23A, 23B, 23C, 23D, 23E, 23
F image data fixing circuit 19 data compression circuit 22A, 22B, 22C image division circuit

Claims (18)

[Claims] 1. An image pickup means for outputting standard image data representing a subject image obtained by picking up an image of a subject, and leaving a portion which becomes a wide display image from the standard image represented by the standard image data outputted from the image pickup means. The image data level that fixes the level of image data in the range of the integral multiple length of the unit block for data compression in the vertical direction at a fixed level in at least one of the upper and lower parts of the standard image. With respect to the fixing means, the image data fixed to a fixed level by the image data / level fixing means, and the image data representing the portion remaining as the wide display image from the standard image, the data amount for one screen after compression is predetermined. Data compression means for compressing data for each unit block so that the data amount becomes A recording device for digital image data, comprising recording control means for recording image data compressed by a data compression means on a recording medium. 2. An identification data generating means for generating identification data indicating that the image data level fixing processing in the image data level fixing means and the data compression processing in the data compression means are provided, and the recording is performed. The control means records the image data compressed by the data compression means in an image data recording area of a recording medium, and the identification data generated by the identification data generating means is recorded in an area other than the image data recording area of the recording medium. The recording apparatus for digital image data according to claim 1, which records in an auxiliary recording area. 3. A reading means for reading the compressed image data recorded in the image data recording area and the identification data recorded in the auxiliary recording area, and a data expansion for expanding the compressed image data read by the reading means. Means and image data other than the image data subjected to the image data level fixing processing among the image data subjected to the data expansion by the data expansion means based on the identification data read by the reading means. 3. The digital image data recording apparatus according to claim 2, further comprising image display control means for controlling the image display so that the displayed image is displayed in a predetermined display area of the display area of the display apparatus. 4. A solid-state electronic image pickup device for generating standard image data having a data amount n times as large as the data amount of unit image data, and representing a subject image obtained by picking up an image of the subject by the solid-state electronic image pickup device. Image pickup means for outputting standard image data, image data division means for dividing the standard image data output from the image pickup means into n unit image data, and unit image data divided into n pieces by the image data division means A length that is an integral multiple of the unit block for data compression in the vertical direction in at least one of the upper and lower parts of the standard image so that the part of the image obtained by combining The image data level fixing means for fixing the level of the image data in the range to The compressed image data and the image data representing the part remaining as the wide display image from the standard image are compressed for each unit block so that the data amount for one screen after compression becomes a predetermined data amount. An apparatus for recording digital image data, comprising data compression means, and recording control means for recording n unit image data data compressed by the data compression means in n unit image data recording areas. 5. An identification data generating means for generating identification data indicating that the image data level fixing processing in said image data level fixing means and the data compression processing in said data compressing means are provided, and said recording The control means divides the n unit image data compressed by the data compressing means into n unit image data recording areas of the recording medium and records the divided unit image data, and the identification data generated by the identification data generating means is recorded as described above. The recording device for digital image data according to claim 4, wherein the recording is performed in an auxiliary recording area other than the image data recording area of the recording medium. 6. A reading means for reading the compressed image data recorded in the image data recording area and the identification data recorded in the auxiliary recording area, and a data decompressing means for decompressing the compressed data read by the reading means. , And image data other than the image data subjected to the image data level fixing processing among the image data subjected to the data expansion by the data expansion means based on the identification data read by the reading means. An image display control means for controlling image display so that an image, which is an image and becomes a wide display image by being combined, is displayed in a predetermined display area of the display area of the display device. 5. A recording device for digital image data according to item 5. 7. A solid-state electronic image pickup device for generating standard image data having a data amount n times as large as the data amount of unit image data, and representing a subject image obtained by picking up an image of the subject by the solid-state electronic image pickup device. An image pickup means for outputting standard image data, an image data dividing means for dividing the standard image data outputted from the image pickup means into n unit image data so that each image represents one frame image, and the image data dividing means. A unit block for data compression in the vertical direction in at least one of the upper and lower parts of the standard image so that the image represented by the n unit image data becomes a wide display image. Image data level fixing means for fixing the level of image data in the range of an integral multiple of With respect to the image data fixed to a fixed level by the fixing means and the image data representing the portion remaining as the wide display image from the standard image, the data amount for one screen after compression becomes a predetermined data amount. Data compression means for performing data compression for each unit block, and recording control means for recording the n unit image data data compressed by the data compression means separately in n unit image data recording areas,
An apparatus for recording digital image data. 8. An identification data generating means for generating identification data indicating that the image data level fixing processing in said image data level fixing means and the data compression processing in said data compressing means are provided, and said recording The control means records the n unit image data data compressed by the data compression means in the unit image data recording area of the recording medium, and the identification data generated by the identification data generating means is recorded on the image of the recording medium. The data is recorded in an auxiliary recording area other than the data recording area.
A recording device for digital image data according to. 9. A reading means for reading the compressed image data recorded in the image data recording area and the identification data recorded in the auxiliary recording area, and a data expansion for expanding the compressed image data read by the reading means. Means for displaying the image represented by the image data of the portion of the image that is the wide display image in the image data that has been subjected to the data expansion by the data expansion means based on the identification data read by the reading means. 9. The digital image data recording apparatus according to claim 8, further comprising image display control means for controlling image display so as to display in a predetermined display area of the display area. 10. A standard image data representing a subject image is obtained by capturing an image of the subject, and the standard image represented by the standard image data obtained by the imaging is placed above and below the standard image so as to leave a portion which becomes a wide display image. The image data level in the range of an integral multiple length of the unit block for data compression in the vertical direction is fixed to a certain level in at least one of the above parts, and is fixed to a certain level by the above image data level fixing process. The compressed image data and the image data representing the portion remaining as the wide display image from the standard image are compressed for each unit block so that the data amount for one screen after compression becomes a predetermined data amount. A method for recording digital image data, in which image data that has been subjected to data compression is recorded on a recording medium. 11. Generation of identification data representing that the image data level fixing process and the data compression process are performed, and the recording process records the image data compressed by the data compression process. 11. The digital image according to claim 10, which is recorded in an image data recording area of a medium, and the identification data generated by the identification data generating process is recorded in an auxiliary recording area other than the image data recording area of the recording medium. How to record data. 12. The compressed image data recorded in the image data recording area and the identification data recorded in the auxiliary recording area are read, and the compressed image data read is decompressed to obtain the read identification data. First, an image represented by image data other than the image data subjected to the image data level fixing process among the image data subjected to the data decompression by the data decompression process is predetermined in the display area of the display device. The method for recording digital image data according to claim 11, wherein the method is displayed in a display area. 13. A subject is imaged using a solid-state electronic image pickup device that generates standard image data having a data amount n times the amount of unit image data, and the standard image data representing the subject image is obtained, and the image pickup is performed. The standard image data obtained by dividing the unit image data into n unit image data, and combining the unit image data divided into n by the image data dividing process, the image obtained as a wide display image is left. In at least one of the upper and lower parts of the standard image, the level of the image data in the range of an integral multiple length of the unit block for data compression in the vertical direction is fixed to a fixed level, and -The image data fixed to a certain level by the level fixing process and the image data representing the portion remaining as the wide display image from the standard image are compressed. Data compression is performed for each unit block so that the data amount for one screen after compression becomes a predetermined data amount, and the n unit image data data-compressed by the data compression process is converted into n unit image data. A method of recording digital image data that is recorded separately in the unit image data recording area. 14. An identification data representing that the image data level fixing process and the data compression process have been performed, and the recording process includes n unit images data-compressed by the data compression process. The data is divided into n unit image data recording areas of the recording medium and recorded,
14. The method for recording digital image data according to claim 13, wherein the identification data generated by the identification data generating process is recorded in an auxiliary recording area other than the image data recording area of the recording medium. 15. The compressed image data recorded in the image data recording area and the identification data recorded in the auxiliary recording area are read, and the compressed image data read is decompressed, and based on the read identification data. hand,
An image represented by image data other than the image data subjected to the image data / level fixing process among the image data subjected to the data decompression by the data decompression process, which is a wide display image by combining. 15. The method for recording digital image data according to claim 14, wherein is displayed in a predetermined display area of the display area of the display device. 16. A subject is imaged using a solid-state electronic image pickup device that generates standard image data having a data amount n times the amount of unit image data, and the standard image data representing the subject image is obtained, and the image pickup is performed. The standard image data obtained by the above is divided into n unit image data so that each represents one frame image, and the image represented by the unit image data divided into n by the image data dividing process is a wide display image. In order to leave the part that becomes, at least one of the upper and lower parts of the standard image,
The level of image data in the range of the length of an integral multiple of the unit block for data compression in the vertical direction is fixed to a fixed level,
Regarding the image data fixed to a certain level by the image data level fixing process and the image data representing the portion remaining as the wide display image from the standard image,
Data compression is performed for each unit block so that the amount of data for one screen after compression becomes a predetermined amount of data, and n unit image data compressed by the data compression process is converted into n unit image data. A method of recording digital image data that is recorded separately in the unit image data recording area. 17. The identification data representing that the image data level fixing process and the data compression process have been performed are generated, and the recording process records the n number of unit image data which are data compressed. 17. The digital image data according to claim 16, which is recorded in a unit image data recording area of the medium, and the identification data generated by the identification data generating process is recorded in an auxiliary recording area other than the image data recording area of the recording medium. Recording method. 18. The compressed image data described in the image data recording area and the identification data recorded in the auxiliary recording area are read, the read compressed image data is decompressed, and based on the read identification data. hand,
An image represented by image data of a portion of the image to be the wide display image in the image data decompressed by the data decompression processing is displayed in a predetermined display area of the display area of the display device. Term
The method for recording digital image data according to item 17.